Abstract
This study explores if unhealthy lipoprotein distribution (LPD) impairs the anabolic and amino acid sensing responses to whey-protein feeding. Thus, if impairment of such anabolic response to protein consumption is seen by the LPD this may negatively affect the skeletal muscle mass. Muscle protein synthesis (MPS) was measured by puromycin labeling in Apolipoprotein E knockout (Apoe KO), characterized by an unhealthy LPD, and wild type mice post-absorptive at 10 and 20 weeks, and post-prandial after whey-protein feeding at 20 weeks. Hypertrophy signaling and amino acid sensing mechanisms were studied and gut microbiome diversity explored. Surprisingly, whey-protein feeding did not affect MPS. p-mTOR and p-4E-BP1 was increased 2 h after whey-protein feeding in both genotypes, but with general lower levels in Apoe KO compared to wild type. At 20 weeks of age, Apoe KO had a greater mRNA-expression for SNAT2, CD98, ATF4 and GCN2 compared to wild type. These responses were not associated with gut microbiota compositional differences. Regardless of LPD status, MPS was similar in Apoe KO and wild type. Surprisingly, whey-protein did not stimulate MPS. However, Apoe KO had lower levels of hypertrophy signaling, was amino acid deprived, and had impaired amino acid sensing mechanisms.
Highlights
This study explores if unhealthy lipoprotein distribution (LPD) impairs the anabolic and amino acid sensing responses to whey-protein feeding
The aim of the current study was to investigate how a characteristic of aging, the unhealthy lipoprotein distribution, influences the sensitivity towards elevated levels of circulating amino acids; the study applied a bolus of whey protein feeding in 20 week old Apoe knockout (KO) mice with an unhealthy LPD compared to wild type (WT) control mice
The unhealthy LPD in the Apolipoprotein E knockout (Apoe KO) mice did neither affect basal Muscle protein synthesis (MPS) nor reveal a different post-prandial MPS after protein feeding compared to WT mice at the selected time points
Summary
This study explores if unhealthy lipoprotein distribution (LPD) impairs the anabolic and amino acid sensing responses to whey-protein feeding. At 20 weeks of age, Apoe KO had a greater mRNA-expression for SNAT2, CD98, ATF4 and GCN2 compared to wild type These responses were not associated with gut microbiota compositional differences. Amino acids sensing and transport across the plasma membrane by L-type amino acid transporter 1 (LAT1)/ solute-linked carrier (SLC) 7A5 and sodium-coupled neutral amino acid transporter 2 (SNAT2)/SLC38A216,17 is orchestrating a series of downstream signaling events. These signals activate the Rag proteins that initiate formation of sites at the lysosome for mTORC1 docking and a ctivation[18,19]. Starvation induced increase in ATF4 expression leads to SNAT2 and LAT1 upregulation, as ATF4 serves as transcription factor for SNAT2 and L AT121,22
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